TWI581875B - Reinforcing bar binding machine - Google Patents

Description

Iron band binding machine

The present invention relates to a brake device for stopping the rotation of a cable wheel after a bundled cable of a predetermined length is fed into the iron band binding machine.

In the iron band binding machine, when the cable of a predetermined length is conveyed, although the conveyance of the cable is stopped, the cable wheel continues to rotate due to the inertia. Therefore, the winding diameter of the cable wound around the cable pulley is expanded, which hinders the next cable conveyance. In order to solve this problem, a fork-shaped brake lever that can be engaged with a cable pulley is provided in the vicinity of the cable wheel as described in the patent document 1 (Japanese Unexamined Patent Publication No. Hei No. Hei No. 11-156746) (the same as the brake device of Patent Document 1) A technique for exposing the brake mechanism in which the brake lever is actuated by a solenoid. Further, in the braking mechanism of Patent Document 1, after the cable is sent out from the cable pulley by a predetermined length, the brake lever is engaged with the peripheral portion of the cable pulley by the solenoid to stop the rotation of the cable pulley.

Therefore, in the brake mechanism of the iron band binding machine shown in FIG. 3 of Patent Document 1, in the structure (including the spring) in which the brake lever rotates around the support shaft, the operation from the solenoid to the brake operation is generated. A number of time delays. Further, for example, when the link mechanism is present between the brake lever and the solenoid that activates the brake lever, the time delay is larger than that of the third drawing of Patent Document 1. Further, when the battery that is a power source such as a solenoid is used for power saving, the battery can be effectively used for a long time.

Further, in the iron band binding machine (including Patent Document 1 and the like), the cable wheel is exposed to the outside of the binding machine body in order to facilitate the loading of the cable wheel with respect to the binding machine body. Moreover, the brake device and the solenoid disposed in the vicinity of the cable pulley are also exposed outside the body of the strapping machine. Therefore, when the iron band binding machine is used outside the house, sand and dust adhere to the solenoid, and the brake cannot be surely performed.

One or more embodiments of the present invention provide a brake device for a cable drum of an iron bar binding machine that improves the braking performance and saves power, and a braking method thereof.

Moreover, one or more embodiments of the present invention provide a brake mechanism for a cable drum of an iron band binding machine that provides improved dustproofness of the brake mechanism.

According to one or more embodiments of the present invention, the iron band binding machine includes: a conveying device 13, 14 for feeding a cable from a cable pulley 20 rotatably disposed in the binding machine body 11; a brake device 30 for the cable The rotation of the reel 20 is performed as a brake; and after the control device 50 sends the cable to the predetermined conveyance amount by the conveyance devices 13, 14, the rotation of the cable reel 20 is braked by the brake device 30.

Moreover, according to one or more embodiments of the present invention, after the cable is rotatably disposed on the cable pulley 20 of the strapping machine body 11 and the cable is sent out by a predetermined amount of conveyance, the rotation of the cable pulley 20 by the brake device 30 is started. brake.

According to the above configuration, after the cable is sent out to the predetermined amount by the transport device, since the brake is started by the brake device for the rotation of the cable pulley, the time delay at the time of braking the cable pulley is reduced, and the braking performance is improved.

Again, in accordance with one or more embodiments of the present invention, from rotatable The cable rim 20 disposed on the strapping machine body 11 and the cable pulley 20 are wound around the iron ribs, and the iron rib binding machine that twists and bundles the cable includes a brake device 30 for the cable The rotation of the reel 20 is used for braking; a metering device 50 calculates the number of times of bundling of the cable fed by the twist; a recording device 52 records the number of times of bundling; and a control device 50 that reads from the recording device 52. When the number of times of bundling is equal to or less than the predetermined number of times of bundling, the brake device 30 brakes the rotation of the cable drum 20.

Further, according to one or more embodiments of the present invention, the cable is twisted and bundled after the cable is wound from the cable drum 20 rotatably disposed in the strapping machine body 11 and wound around the iron rib. In the tendon binding machine, the brake processing system includes the following steps: calculating the number of times of bundling to twist the cable; and braking the rotation of the cable wheel 20 by the braking device 30 when the number of times of bundling is less than the predetermined number of times of bundling.

According to the above configuration, when the number of times of bundling of the cable fed by the transport device is less than or equal to the reference value, the brake device brakes the rotation of the cable wheel. In other words, when the number of times of the bundle of the predetermined length is equal to or greater than the reference number of times, power is saved by omitting the brake processing, and the use time of the power source of the transport device is prolonged, so that the power source of the transport device can be effectively utilized for a long time.

Moreover, according to one or more embodiments of the present invention, the iron band binding machine includes: a conveying device 13, 14 for feeding a cable from a cable pulley 20 rotatably disposed in the binding machine body 11; a brake device 30, The rotation of the cable pulley 20 is braked; a detecting device 57 detects a power supply voltage that activates the conveying devices 13, 14; and a control device that causes the braking device when the detected power supply voltage is greater than or equal to a predetermined reference value Brake start time ratio of device 30 Quasi-time is early.

Further, according to one or more embodiments of the present invention, the brake processing method of the cable wheel includes the steps of: feeding the cable from the conveying device 13, 14 from the cable pulley 20 rotatably disposed on the strapping machine body 11; The power supply voltage for starting the transport devices 13 and 14 is turned on. When the power supply voltage is detected to be equal to or greater than a predetermined reference value, the braking time of the braking device 30 that stops the rotation of the cable pulley 20 is earlier than the reference time.

According to the above configuration, when the power supply voltage of the transport device is above a predetermined reference value, since the transport speed of the cable becomes faster, only the portion where it is faster, the timing of applying the brake to the cable pulley is earlier, and conversely, the brake is applied. Timing delay. That is, when the power supply voltage of the transport device is equal to or higher than the predetermined reference value, the braking start time of the stopping device that stops the rotation of the cable wheel is earlier than the reference time, and the braking is applied at an appropriate timing, thereby improving the braking performance.

On the other hand, when the power supply voltage of the transport device is lower than the reference value, the transport speed of the cable returns to the normal state, and the power source voltage of the transport device is higher than the predetermined reference in the ON time of the drive source of the transport device, for example, the solenoid. The situation above the value is short, thus saving power. In other words, when the timing of the brake is applied by the power supply voltage of the transport device, the inertia rotation of the cable pulley can be surely stopped, and unnecessary power consumption can be removed.

Moreover, according to one or more embodiments of the present invention, the iron band binding machine includes: a cable pulley 20 rotatably disposed on the strapping machine body 11; a brake device 30 engageable with the cable pulley 20 The engaging portion 21; a driving device 32, 60 driving the braking device 30; and a cover 17 separating the driving device 32, 60 from the cable pulley 20.

According to the above configuration, the drive device and the cable pulley are separated by a cover, and since the drive is covered by the cable pulley, even if the iron band binding machine is used outdoors, the sand dust does not adhere to the drive device and can be surely performed. brakes. That is, it does not interfere with the filling property of the cable wheel, and it is possible to prevent dust or the like from adhering to the driving device, and it is possible to improve dustproofness.

Moreover, according to one or more embodiments of the present invention, the iron band binding machine includes: a braking device 30 that is engaged with the engaging portion 21 of the cable pulley 20 rotatably disposed in the binding machine body 11; a driving device 32 60, driving the braking device 30; a biasing device 36 is suspended from the braking device 30, and the braking device 30 is engaged with the engaging portion 21 to return the braking device 30 to the initial position. Further, the brake device includes a stopper lever (30) that is engaged with the engagement portion (21) of the cable pulley (20), and the first suspension portion (36B) of the biasing device (36) is engaged with the strapping machine. The body (11) and the second suspension portion (36C) are engaged with the stop lever (30).

According to the above configuration, since the brake device is directly suspended from the biasing device, the biasing force of the biasing device can directly return the braking device to the initial state. That is, the biasing force of the biasing means is not wasted, and since the useless force is not applied to each element such as the driving means, the braking device can be effectively restored.

Other features and effects will become more apparent from the description of the embodiments and the appended drawings.

10‧‧‧ iron band binding machine

11‧‧‧ iron band binding machine body

12A, 12B‧‧‧ cable access

13‧‧‧Transport gears (conveyor)

14‧‧‧Transport motor (conveyor)

15‧‧‧ Guides

16‧‧‧Torque motor

17‧‧‧ cover (dustproof device)

20‧‧‧Cable wheel

20A, 20B‧‧ ‧ flange

21‧‧‧Cable wheel engagement

24‧‧‧ iron bars

30‧‧‧stop lever (brake device)

32‧‧‧Solenoid (brake device (drive device for brake device))

34‧‧‧Axis

36‧‧‧Helical coil spring (biasing device)

36B‧‧‧First suspension

36C‧‧‧Second suspension

40‧‧‧ bracket

50‧‧‧CPU (control device or metering device)

52‧‧‧ memory (recording device)

53‧‧‧Battery (power supply for conveyors)

57‧‧‧Voltage detection circuit (voltage detection device)

58‧‧‧ bracket

60‧‧‧ brake motor

61‧‧‧ Gears

62‧‧‧Reducing gear

S‧‧‧stop device

W‧‧‧ cable

Fig. 1 is a perspective view of the entire main part of the iron band binding machine according to the first embodiment of the present invention.

Fig. 2 is a plan view showing the iron band binding machine shown in Fig. 1.

Fig. 3 is a side view shown in Fig. 1.

Fig. 4 is a cross-sectional view taken along line X-X of Fig. 3.

Fig. 5 is an overall perspective view of the brake mechanism shown in Fig. 4.

Fig. 6 is an exploded perspective view of the brake mechanism shown in Fig. 5, and a side view of the iron band binding machine.

Fig. 7 is a plan view showing the main part of the brake mechanism of the brake mechanism shown in Fig. 4.

Figure 8 is a side view of Figure 7.

Fig. 9 is a perspective view showing the entire brake mechanism according to the second embodiment of the present invention.

Fig. 10 is an exploded perspective view of the brake mechanism shown in Fig. 9.

Figure 11 is a block diagram of the iron band binding machine shown in Figure 1.

Fig. 12 is a flow chart showing the bundling mode of the iron band binding machine shown in Fig. 1.

Fig. 13 is a view showing the timing of the operation of the solenoid shown in Fig. 1.

Fig. 14 is a flow chart showing the power saving mode of the iron band binding machine shown in Fig. 1.

Fig. 15 is a flow chart showing the brake timing change mode of the iron band binding machine shown in Fig. 1.

Hereinafter, the brake mechanism of the cable pulley in the iron band binding machine according to the first embodiment of the present invention will be described based on the first to eighth and eleventh drawings. Fig. 1 is a perspective view of the entire main part of the iron band binding machine according to the first embodiment of the present invention. Fig. 2 is a plan view showing the iron band binding machine shown in Fig. 1. Fig. 3 is a side view shown in Fig. 1. Fig. 4 is a cross-sectional view taken along line X-X of Fig. 2; First 5 is a perspective view of the entire brake mechanism shown in FIG. 4. Fig. 6 is an exploded perspective view of the brake mechanism shown in Fig. 5. Further, Fig. 11 is a block diagram of the iron band binding machine shown in Fig. 1.

(Summary structure of iron band binding machine)

As shown in FIGS. 1 to 3, the iron band binding machine 10 has a binding machine body 11 and a cable pulley 20 detachably disposed with respect to the binding machine body 11. The cable pulley 20 operates a lever (not shown) to form a detachable configuration. The strap body 12 is provided with passages 12A and 12B for the binding cable W (see FIGS. 2 and 3). As shown in Fig. 2, between the passages 12A and 12B, the pair of conveying gears 13 constituting the conveying device are disposed to sandwich the cable W. As shown in FIG. 3, the strapping machine body 11 is provided with a transport motor 14 that rotates the transport gear 13. Further, a trigger 18 (see FIG. 3) is disposed on the strapping machine body 11, and the transport motor 14 is driven by the trigger operation of the trigger 18.

A guide 15 is disposed on the transport direction side (the right side in FIG. 3) of the strapping machine body 11, and the cable W is bent in a loop shape (indicated by a two-point lock line in FIG. 3). Further, a twisting motor 16 is disposed on the binding machine 11, and a torsion fork (not shown) is coupled to the twisting motor 16. Then, the torsion fork is driven by the rotation of the torsion motor 16, and the ring-shaped cable W wound around a plurality of (two in FIG. 3) iron bars 24 is twisted.

In other words, the torsion fork rotates forward, and the loop-shaped cable W is twisted in and out, twisted, and then reversed and retracted to the initial position. Further, the twisted processed cable W is cut by a cutter (not shown) that is interlocked with a torsion fork (not shown). Further, since these mechanisms are the same as those of the well-known mechanisms, the above detailed description is omitted.

(There is a structure about the brake mechanism)

As shown in Fig. 4, the cable pulley 20 has a pair of flanges 20A and 20B. A plurality of substantially zigzag-shaped engaging portions 21 are formed at one edge of the flange 20A at a predetermined interval (see FIG. 3). Corresponding to the engaging portion 21, a stopper lever 30 as a brake device is provided. As shown in Fig. 5, the brake device S including the stopper lever 30 includes a solenoid 32 as a driving means, a ring 33, a shaft 34, a coupling wheel 37, a coil spring (hereinafter referred to as a spring) 36, and a hollow pin 38. And a bracket 40. The bracket 40 supports the shaft 34 while fixing the solenoid 32. The bracket 40 is disposed in the cover 17 as a dustproof device of the strapping machine body 11 as shown in the two-point lock line of Fig. 2 and Fig. 4 .

As shown in Fig. 5, the core 32A of the solenoid 32 is slidably disposed, and when the solenoid 32 is ON, the length L of the core 32A is pulled into the solenoid 32 (see Fig. 7). Further, when the solenoid 32 is OFF, the iron core 32A is held at the initial position shown in FIG. Switching of ON and OFF of the solenoid 32 is controlled by the CPU 50 shown in Fig. 11.

As shown in Fig. 6, one end of the core 32A and the ring 33 is coupled via a pin 33A. On the other hand, the other end of the ring 33 constituting the link mechanism and the connecting wheel 37 fixed to the shaft 34 are coupled by the pin 33B, and the shaft 34 is rotatably disposed on the bracket 40 via the connecting wheel 37. Further, the shaft 34 passes through the tubular portion 40A of the bracket 40. Then, when the core 32A and the ring 33 slide, the shaft 34 rotates about the axis. Further, on the shaft 34, the front end thereof has a cutter portion 34A which is D-cut.

The shaft 34 protruding from the cylindrical portion 40A of the bracket 40 passes through the D-cut hole 30A of the stopper lever 30 together with the bearing 35, the hollow pin 38, and the coil portion 36A of the spring 36. Then, the stopper lever 30 or the like is pulled out from the shaft 34 by the stopper 39.

The D cutter portion 34A of the shaft 34 corresponds to the hole 30A of the stopper lever 30, and the stopper lever 30 is rotated about the shaft 34 by the rotation of the shaft 34. In the stopper lever 30, an engagement portion 31 that is slightly L-shaped and that engages with the engagement portion 21 of the cable pulley 20 is formed (see FIG. 3).

Then, the solenoid 32 shown in FIG. 6 is provided inside the cover 17 shown in FIGS. 2 and 4 together with the shaft 34 and the bracket 40. That is, the cover 17 is composed of a body cover 17A covering one side of the strapping machine body 11 and a body cover 17B covering the other side, and the space between the body cover 17A and the body cover 17B is substantially sealed. That is, the shaft 35 of the shaft 34 is fitted and fixed to the opening 41, and other elements (not shown) are fitted into the openings 42, 43, and 44. Thus, the solenoid 32 and the cable pulley 20 are separated by a cover 17, and the solenoid 20 and the tubular portion 40A of the bracket 40 are covered by the cable pulley 20 to be hidden. Further, in the sliding portion of the shaft 34 that rotates the stopper lever 30, the tubular portion 40A of the bracket 40 is disposed inside the cover 17 and is hidden from the outside, and the sliding portion of the shaft 34 disposed outside the cover 17 is also The hollow pin 38 is hidden from the bearing 35.

As shown in Fig. 6, the coil portion 36A of the spring 36 is inserted into the coil holder 38A of the hollow pin 38, and the spring 36 is supported by the hollow pin 38. As shown in Fig. 3, the suspension portion 36B of the spring 36 is engaged with the strapping machine body 11, and the suspension portion 36C is engaged with the outside of the stopper lever 30 (refer to Fig. 5). Therefore, the spring 36 is often biased against the stop lever 30 in the direction of the arrow shown in Fig. 3 (i.e., counterclockwise).

In other words, since the stopper device S has a ring mechanism between the stopper lever 30 and the solenoid 32 that operates the stopper lever 30, the time for braking the brake is delayed as compared with the third diagram of Patent Document 1 described above. Become bigger. And, stop The standby mode in the device S, that is, the OFF state of the solenoid 32 is the state shown in Figs. 1 to 5 .

(Structure of the control system of the iron band binding machine)

The iron band binding machine 10, as shown in FIG. 11, includes a CPU 50 having a timing function, a memory 52, a battery 53, a sensor 54, a trigger SW (SW is abbreviated as a switch) 56, a voltage detecting circuit 57, The solenoid 32, the torsion motor 16, and the delivery motor 14 are provided. The CPU 50 controls the entire operation of the iron band binding machine 10, for example, when the switching signal is input from the trigger SW 56 to the CPU 50, the bundling process is performed based on the switching signal. Further, as described above, the CPU 50 has a timer 51 for counting. Further, the CPU 50 is a control device and a metering device.

In the memory 52 as a recording device, a program is recorded which controls various processes of the iron band binding machine 10. For example, in the memory 52, the time when the solenoid 32 is ON is also recorded. The sensor 54 is configured to detect the rotation of the transport gear 13. That is, the magnet that rotates together with the conveying gear 13 is configured by the Hall IC as the sensor 54. Then, the sensor 54 detects that the transport gear 13 is half-rotated, and the CPU 50 also judges whether the cable W is sent out by a predetermined length, for example, 80 cm at a time, based on the detection signal of the sensor 54 with the number of revolutions of the transport gear 13.

The battery 53 is used as a power source for the CPU 50, the solenoid 32, the torsion motor 16, and the conveyance motor 14, and supplies electric power for starting the solenoid 32 or the CPU 50. Further, the voltage detecting circuit 57 as the voltage detecting means detects the voltage of the battery 53, and the detected value data which is the detection result is input to the CPU 50. Then, the CPU 50 compares the power supply voltage of the battery 53 which becomes the input detection value data with the reference voltage recorded in the memory 52. Moreover, the wiring system of the battery 53 The drawings other than the voltage detecting circuit 57 are omitted. This is to prevent staggering when a plurality of wires are connected to the respective electronic components such as the CPU 50.

The trigger SW 56 is linked to the pulling operation of the trigger 18 shown in FIG. 3 to form a structure in which the switch is ON. Then, when the trigger SW56 is ON, the CPU 50 rotates the conveyance motor 14, that is, the conveyance gear 13, to pull the cable W toward the conveyance direction. That is, the conveyance motor 14 and the torsion motor 16 are rotationally driven in accordance with a drive signal from the CPU 50. Moreover, the torsion motor 16 can be rotated forward and reversed.

Further, the solenoid 32 slides the iron core 32 from the initial position (the position shown in FIG. 4) in the pull-in direction based on the drive signal from the CPU 50 (that is, the ON signal). Then, when the drive signal is supplied from the CPU 50, the solenoid 32 is turned OFF, and the stopper lever 30 shown in Fig. 5 is returned to the initial position (the position shown in Fig. 3) by the biasing force of the spring 36.

(The role of this embodiment)

When the trigger 18 of the iron band binding machine 10 shown in FIG. 3 is pulled, the cable W wound around the cable pulley 20 is conveyed by the transport gear 13 by a predetermined length and wound around a plurality of iron bars 24. . Then, before the end of the conveying operation of the cable W, the solenoid 32 is turned ON, and the iron core 32A is sucked. By this suction operation, the stopper lever 30 rotates in the arrow direction (clockwise direction) of Fig. 8 against the biasing force of the spring 36.

Therefore, as shown in Fig. 8, the engaging portion 31 of the stopper lever 30 is engaged with the engaging portion 21 of the cable pulley 20, and the cable pulley 20 is stopped from rotating. Therefore, since the cable pulley 20 does not rotate due to inertia, the diameter of the cable W does not become large, and the cable can be smoothly conveyed all the time. Moreover, Figure 7 is the picture shown in Figure 4. A plan view of the main part of the car mechanism during the braking action. Figure 8 is a side view of Figure 7.

Then, after a predetermined period of time, the solenoid 32 is turned OFF, and the stopper lever 30 is rotated by the biasing force of the spring 36 in the arrow direction (counterclockwise direction) of FIG. 3, and the core 32A is also slid toward the initial position. (Refer to Figure 4). That is, since the spring 36 is directly suspended from the stopper lever 30, the biasing force of the spring 36 directly returns the stopper lever 30 to the initial position. Therefore, the biasing force of the spring is not wasted, and since the useless force is not applied to each member such as the iron core 32A or the like, the stopper lever 30 can be effectively returned.

Thereafter, the torsion motor 16, that is, the twisting fork, is driven in accordance with the driving signal of the CPU 50, and the cable W is twisted and bundled. Further, after the end of the conveying operation of the cable W, the CPU outputs the driving signal to the torsion motor 16.

Next, the above-described bundling process (synonymous with the bundling mode) will be described based on the flowchart shown in FIG. Here, the processing of the iron band binding machine 10 shown in Fig. 1 is performed by the CPU 50 (see Fig. 11), and is shown in the flowchart of Fig. 12. This program is previously stored in the program area of the memory 52 of the iron band binding machine 10 (see Fig. 11). Further, Fig. 13 is a view showing the timing of the operation of the solenoid 32 shown in Fig. 1.

(bundling mode)

In step 100 shown in Fig. 12, it is judged whether or not the trigger SW 56 (refer to Fig. 11) is ON. That is, the flip-flop 18 shown in Fig. 3 is pulled and judged whether or not the trigger SW 56 is ON. When the step 100 is affirmative, that is, when the trigger SW 56 is ON, in step 102, the CPU 50 drives the transport motor 14. Moreover, when the step 100 is negative, the wait trigger SW 56 is turned ON.

In step 104, it is determined whether or not the number of rotations of the conveyance gear 13 shown in Fig. 2 is a reference value (synonymous with "a predetermined conveyance amount before a predetermined length"). Here, the reference value is the reference number of revolutions of the number of rotations until the predetermined amount of conveyance before the conveyance gear 13 conveys the cable W to a predetermined length.

That is, by detecting the rotation of the conveying gear 13 by the sensor 54 shown in Fig. 11, the CPU 50 determines whether or not the conveying gear 13 is rotated by a reference value, for example, 17. When the determination in step 104 is affirmative, that is, when the number of rotations of the conveyance gear 13 reaches the reference number of revolutions, in step 106, the solenoid 32 shown in Fig. 11 is turned ON. Moreover, when the step 104 is negative, the number of rotations of the conveying gear 13 is waited for the reference number of revolutions.

In step 108, it is judged whether or not the number of revolutions of the conveying gear 13 reaches the reference value (for example, 17 turns). Here, the reference value is a reference number of rotations for determining whether or not the conveyance gear 13 is a number of rotations for sending the cable W by a predetermined length. That is, step 108 determines whether or not the half rotation is performed from the reference rotation (17 rotation) of step 104.

When the step 108 is affirmative, that is, when the number of rotations of the conveyance gear 13 reaches the reference number of revolutions, in step 110, the CPU 50 stops the conveyance motor 14 and starts the counting of the timer 51 shown in Fig. 11. Here, the solenoid 32 is turned ON before the cable is conveyed, and the timing from the actuation of the solenoid 32 to the braking of the cable pulley 20 is considered. Further, when the step 108 is negative, the rotation of the conveying gear 13 is waited for the reference number of revolutions.

In step 112, the CPU 50 determines whether or not the measured value of the timer 51 is the reference value of the brake release time, for example, 0.1 second (refer to Fig. 13). When the step 112 is affirmative, that is, the brake release time (measurement value is 0.1 second), the solenoid 32 is turned OFF in step 114.

When step 112 is negative, it waits for it to become the reference time. Here, the brake is applied to the cable drum 20 for 0.1 second, and it is experimentally the time for the rotation of the cable pulley 20 to be surely stopped, but the time when the brake is released. Further, the brake release time is arbitrarily changed to 0.08 seconds or 0.12 seconds due to the structural change of the link mechanism of the stopper device S.

In step 116, a twisting process is performed. In the twisting process, the twisting motor 16 is rotated forward, and the cable W wound around the plurality of intersecting iron bars 24 (see FIG. 3) is twisted by a twisting fork (not shown) (see the two-point lock line in FIG. 3). The twisting process is performed, and the twisting motor 10 is reversed to return the twisting fork to the initial position. Then, when the processing of step 116 ends, the processing of the main flow ends. Further, the bundling mode shown in Fig. 12 is repeated every time the trigger SW 56 is turned ON.

According to the present embodiment, the predetermined amount of conveyance (the number of revolutions of the step 104) before the cable W is sent out by the conveyance gear 13 by a predetermined length is sent, and the rotation of the cable pulley 20 is started by the stopper S, so The time delay during the braking of the cable wheel 20 is reduced, and the braking performance can be improved.

Further, the processing of the power saving mode and the braking timing change mode of the iron band binding machine 10 will be described below based on the flowcharts shown in Figs. 14 and 15 .

(Power saving mode)

In step 120 shown in Fig. 14, it is judged whether or not the trigger SW 56 is ON. When step 100 is affirmative, that is, when the trigger 18 is pulled, in step 122, the CPU 50 drives the delivery motor 14. In step 124, the number of bundles is read from the memory 52 shown in Fig. 11. Here, for calculating the number of bundles, Each time the cable pulley 20 shown in FIG. 1 is loaded in the strapping machine body 11, the CPU 50 as a measuring device lists the measurement values of the number of bundles in the memory area of the memory 52, and starts measuring. . Further, the cable W wound around the cable pulley 20 is generally subjected to a bundling process 120 times.

In step 126, it is determined whether the number of times of bundling is below the reference value. That is, the CPU 50 determines whether or not the measured value is, for example, 40 times or less. When the step 126 is affirmative, that is, when the measured value is 40 or less, in step 128, the CPU 50 performs the braking process. This brake processing is as shown in Fig. 12, which is the respective processing of steps 104 to 114.

After the braking process of step 128 is completed, in step 130, the twisting process (the same process as step 116 of Fig. 12) is performed. When the step 126 is negative, that is, when the measured value is 40 or more, the process proceeds to step 130. That is, when the step 126 is negative, the braking process of step 128 is omitted. Here, the brake processing is performed only when the measured value is less than 40 times, and the maximum winding diameter of the cable W and the diameter difference of the outer circumferences of the flanges 20A and 20B of the cable pulley 20 become small, so that the cable pulley 20 is used. When inertially rotating, the cable W will protrude from the flanges 20A and 20B and cause an obstacle to the next cable conveyance.

On the other hand, when the measured value is 40 or more, the brake processing is omitted, and since the maximum winding diameter of the cable W and the diameter difference of the outer circumferences of the flanges 20A and 20B of the cable pulley 20 become large, even the cable pulley 20 does the inertial rotation, and the cable W does not protrude from the flanges 20A and 20B.

After the end of the twisting process of step 130, in step 132, the number of bundlings is calculated. That is, the CPU 50 sets the measured value to 21 in the current measured value, for example, 20 in increments of one. Then, in step 134, the metering value is for example 21 is recorded in the memory 52. Moreover, the measured value of the record is read in the next step 124. When the processing of step 134 ends, the processing of the main flow ends. The power saving mode shown in Fig. 14 is repeated every time the trigger SW56 is turned ON.

In the present embodiment, when the number of times the cable W of a predetermined length conveyed by the transport gear 13 is twisted and bundled is below the reference value (specifically, when step 126 is affirmative), the rotation of the cable pulley 20 is stopped. The device S brakes. That is, according to the present exemplary embodiment, when the number of times of the bundle W of the predetermined length is equal to or greater than the reference number of times (specifically, when step 126 is negative), power is saved by omitting the brake processing, as shown in FIG. The use time of the battery 53 is extended, and the battery 53 can be effectively utilized for a long time.

(Brake time change mode)

In step 140 shown in Fig. 15, it is judged whether or not the trigger SW 56 is ON. When step 140 is affirmative, that is, when the trigger 18 is pulled, in step 142, the CPU 50 drives the delivery motor 14. In step 144, the CPU 50 detects the voltage value of the battery 53 via the voltage detecting circuit 57 shown in Fig. 11. That is, the CPU 50 outputs the voltage value data input from the voltage detecting circuit 57. Here, for the battery ground pressure, for example, 16 V when fully charged (ie, synonymous with the highest voltage), the lowest voltage (ie, the voltage before the power source has not been turned ON) is, for example, 14.4 V. Then, the memory 52 shown in Fig. 11 stores a reference value of the battery voltage, for example, 15 V, in its memory area.

In step 146, it is determined whether the voltage value of the battery is below the reference value. That is, the CPU 50 determines whether or not the battery voltage is 15 V or less. When the step 146 is affirmative, that is, when the battery voltage value is 15 V or less, in step 148, the CPU 50 starts the driving timing of the solenoid 32 shown in FIG. 11 (when the braking is started). As a reference value, for example, the reference rotation (17 rotation) in step 104. That is, during the 17 rotation, the solenoid 32 is driven to apply the brake.

When the step 146 is negative, that is, when the battery voltage value is 15 V or more, in step 150, the start driving timing of the solenoid 32 is earlier than the reference rotation (17 rotation). For example, since the start braking time of the stopper device S is earlier than the reference time, the solenoid 32 is driven with a 16-half rotation as a reference value and braking is performed.

Here, in the process of the setting step 150, when the battery voltage is higher than the reference value, since the conveying speed of the cable W is increased, the timing of braking the cable wheel 20 must be advanced. At this time, since the current flowing through the solenoid 32 is the same as the example shown in FIG. 13, the ON time of the solenoid 32 becomes long.

On the other hand, when the battery voltage is lower than the reference value, the transport speed of the cable W returns to the normal (synonymous with the standard), and is the same as the example of Fig. 12. That is, since the ON time of the solenoid 32 is shorter than the step 150, power can be saved. Therefore, due to the timing change of the braking by the battery voltage, the inertial rotation of the cable 20 can be surely stopped, and unnecessary power consumption can be removed.

After the processing of step 148 or step 150 is completed, in step 152, the braking process is performed. This braking process is the processing of steps 104 to 114 shown in Fig. 12. After the end of the braking process at step 152, in step 154, the twisting process is performed (the same processing as step 116 of Fig. 12). At the end of the twisting process of step 154, the processing of the main flow ends. The brake timing change mode shown in Fig. 15 is repeated every time the trigger SW56 is turned ON.

In the present embodiment, when the power supply voltage of the battery 53 is equal to or greater than a predetermined reference value (NO in step 146), since the transport speed of the cable W is increased, If the speed is increased, the timing of applying the brake to the cable wheel 20 is not advanced, and the timing of applying the brake is reversed. That is, according to the present embodiment, when only the power source voltage of the battery 53 is equal to or higher than the predetermined reference value, the brake start time of the stopper device S for stopping the rotation of the cable pulley 20 is earlier than the reference time, so that the brake can be applied with an appropriate timing. Improve braking performance.

On the other hand, in the present embodiment, when the battery voltage is lower than the reference value (YES at step 146), since the conveying speed of the cable W returns to normal, the ON time of the solenoid 32 is longer than the step 150. Short and save electricity. In other words, according to the present embodiment, since the battery voltage is changed and the timing of applying the brake is changed, the inertia rotation of the cable pulley 20 can be surely stopped, and unnecessary power consumption can be removed.

Further, the power source that drives the stopper lever 30 may be a motor or the like in addition to the solenoid 32. Further, by changing the link structure between the stopper lever 30 and its drive source, the predetermined conveyance amount in the first or second aspect of the patent application, for example, the reference value of the number of rotations of the gear 13 (refer to step 104) ) can be changed arbitrarily.

In addition, the flow of the processing of each of the programs described in the above-described embodiments (see FIG. 12, FIG. 14 and FIG. 15) is an example, and can be appropriately modified without departing from the spirit of the invention. That is, the strapping mode, the power saving mode, or the braking timing mode can be arbitrarily combined.

In the present embodiment, the solenoid 32 shown in Fig. 6 and a portion of the shaft 34 for rotating the stopper lever 30 and the bracket 40 are disposed in the cover 17 shown in Figs. 2 and 4 The sliding portion of the shaft 34 is disposed in the hollow pin 38 with the cylindrical portion 40A of the bracket 40 and the bearing 35, so that the stop lever 30 rotates. The solenoid 32 and the shaft 34 are completely covered by the cover 17 to be hidden.

That is, according to the present embodiment, the solenoid 32 and the cable pulley 20 are separated by a cover 17, and since the solenoid 20 is covered by the cable pulley 20, even if the iron band binding machine 10 is used outdoors, the dust does not occur. It will adhere to the solenoid 20, and the braking operation can be surely performed. Therefore, the filling property of the cable wheel is not impaired. Further, since the sliding portion of the shaft 34 located outside the cover 17 is also covered by the hollow pin 38, the bearing 35, and the like, the dustproof property is improved, and the sliding portion is free from dust and dust, and the braking operation can be performed more surely. In particular, the bearing 35 is adjacent to the hollow pin 38, and since the portion of the shaft 34 that exposes the outer side of the bearing 35 is covered by the hollow pin 38, it is possible to prevent dust or the like from adhering to the bearing 35.

Further, the sliding portion is disposed so as to cover the periphery of the shaft 34 so as to be slidable, and the cylindrical portion 40A of the bracket 40 and the bearing 35 are not necessarily limited to be provided in the hollow pin 38.

(Second embodiment)

Hereinafter, a second embodiment in which the drive device is changed from a solenoid to a dedicated motor that can be reversed and reversed will be described with reference to FIGS. 9 and 10 . Here, Fig. 9 is a perspective view of the entire brake mechanism according to the second embodiment of the present invention. Fig. 10 is an exploded perspective view of the brake mechanism shown in Fig. 9. Further, the same elements as those of the first embodiment are given the same reference numerals. Further, the ninth diagram corresponds to the fifth diagram in the first embodiment, and the tenth diagram corresponds to the sixth diagram in the first embodiment.

In the stopper device of the present embodiment, a brake motor (hereinafter referred to as a motor) 60 is fixed to the bracket 58. The gear 61 of the motor 60 is meshed with a reduction gear 62 fixed to the shaft 34. Further, a tubular portion 59 through which the shaft 34 is inserted is disposed on the bracket 58. Further, in the present embodiment, the arrangement shown in Fig. 6 is not arranged. A connecting member such as the link 33 and the connecting wheel 37. The other structure is the same as the examples of Figs. 5 and 6. Therefore, in the above-described stopper device, as in the fourth embodiment, the cover (not shown) separates the motor 60 and the cable pulley 20 as the drive device by the portion of the bearing 35.

According to the present embodiment, since the stopper lever 30 is directly rotated by the rotation of the reduction gear 62 in the motor 60 that can be rotated forward and backward, the release of the brake becomes rapid. Further, according to the present embodiment, since the spring 36 shown in Fig. 9 is not required, the number of members can be reduced. The other operational effects are the same as those of the first embodiment, and thus detailed description thereof will be omitted.

While the present invention has been described with respect to the specific embodiments thereof, various modifications and changes can be made to the invention without departing from the scope of the invention. Therefore, all the changes and modifications in the scope of the spirit and scope of the invention are included in the scope of the claims.

[Possibility of industrial use]

The invention can be applied to a brake device and a brake method for a cable wheel in an iron band binding machine.

10‧‧‧ iron band binding machine

11‧‧‧ iron band binding machine body

15‧‧‧ Guides

16‧‧‧Torque motor

20‧‧‧Cable wheel

32‧‧‧Solenoid (brake device (drive device for brake device))

W‧‧‧ cable

Claims (9)

An iron band binding machine that feeds a cable from a cable wheel rotatably supported by the body of the binding machine, winds the supplied cable around the iron rib, and twists the wound cable to bind the above The iron rib includes: a solenoid having a core configured to be slidable; a shaft rotatable about the axis; and a coupling member connecting the core and the shaft so as to rotate around the axis along with the sliding of the core The shaft and the stopper lever are attached to the shaft, and are rotated about the shaft by the rotation of the shaft, and are engaged with the cable pulley to stop the rotation of the cable pulley with rotation. The iron band binding machine according to claim 1, wherein the iron band binding machine further has a cover, and is disposed on the iron in a manner of separating a space in which the solenoid is disposed and a space in which the stopping lever is disposed. The ribbing machine body. The iron band binding machine according to claim 2, wherein the cover has an opening through which the shaft penetrates, and a bearing that supports the shaft is provided in the opening. The iron band binding machine according to claim 1, wherein the connecting member supports one end of the shaft, and the stopping lever connects the other end of the shaft. The iron band binding machine according to claim 1, wherein the iron band binding machine further has a spring biased in a direction opposite to a rotation direction of the stopping lever. The iron band binding machine according to claim 5, wherein the spring has a coil portion that is inserted through the shaft. The iron band binding machine according to claim 1, wherein the iron band binding machine further comprises a conveying motor for conveying a cable wound on the cable wheel; the shaft is opposite to the conveying The rotating shaft of the motor is vertically arranged. The iron band binding machine according to claim 5, wherein the stopping lever rotates on the one hand against the biasing force of the spring via the shaft when the solenoid is turned on and the core slides. When the solenoid is turned off, it is configured to return to the initial position by the biasing force of the spring. The iron band binding machine according to claim 1, wherein the iron band binding machine further comprises: a conveying motor configured to send a cable wound around the cable wheel; and a cover to separate The space in which the solenoid is disposed and the space in which the stopper lever is disposed are disposed in the body of the iron band binding machine; the connecting member is disposed in a space in which the solenoid is disposed; and the shaft penetrates the cover, and The solenoid is disposed at a position facing the transport motor by the cover.